Lesson 4

Introduction to Linear Relationships

Let’s explore some relationships between two variables.

4.1: Number Talk: Fraction Division

Find the value of \(2\frac58 \div \frac12\).

4.2: Stacking Cups

We have two stacks of styrofoam cups.

  • One stack has 6 cups, and its height is 15 cm.
  • The other stack has 12 cups, and its height is 23 cm.

How many cups are needed for a stack with a height of 50 cm?

 

6 styrafoam cups 15 centimeters, 12 styrafoam cups 23 centimeters

4.3: Connecting Slope to Rate of Change

  1. If you didn’t create your own graph of the situation before, do so now.

    graph, horizontal axis, number of cups, scale 0 to 40, by 5's. vertical axis, height in centimeters, scale 0 to 50, by 10's.
  2. What are some ways you can tell that the number of cups is not proportional to the height of the stack?
  3. What is the slope of the line in your graph? What does the slope mean in this situation?
  4. At what point does your line intersect the vertical axis? What do the coordinates of this point tell you about the cups?
  5. How much height does each cup after the first add to the stack?
     

Summary

Andre starts babysitting and charges \$10 for traveling to and from the job, and \$15 per hour. For every additional hour he works he charges another \$15. If we graph Andre's earnings based on how long he works, we have a line that starts at \$10 on the vertical axis and then increases by \$15 each hour. A linear relationship is any relationship between two quantities where one quantity has a constant rate of change with respect to the other.

graph, horizontal axis, time in hours, scale 0 to 9, by 1's. vertical axis, amount earned in dollars, scale 0 to 140, by 20's.

We can figure out the rate of change using the graph. Because the rate of change is constant, we can take any two points on the graph and divide the amount of vertical change by the amount of horizontal change. For example, take the points \((2, 40)\) and \((6, 100)\). They mean that Andre earns \$40 for working 2 hours and \$100 for working 6 hours. The rate of change is \(\frac{100-40}{6-2} = 15\) dollars per hour. Andre's earnings go up \$15 for each hour of babysitting.

Notice that this is the same way we calculate the slope of the line. That's why the graph is a line, and why we call this a linear relationship. The rate of change of a linear relationship is the same as the slope of its graph.

With proportional relationships we are used to graphs that contain the point \((0,0)\). But proportional relationships are just one type of linear relationship. In the following lessons, we will continue to explore the other type of linear relationship where the quantities are not both 0 at the same time.

Glossary Entries

  • linear relationship

    A linear relationship between two quantities means they are related like this: When one quantity changes by a certain amount, the other quantity always changes by a set amount. In a linear relationship, one quantity has a constant rate of change with respect to the other.

    The relationship is called linear because its graph is a line.

    The graph shows a relationship between number of days and number of pages read.

    When the number of days increases by 2, the number of pages read always increases by 60. The rate of change is constant, 30 pages per day, so the relationship is linear.

    Graph of line. Points plotted on line include 1 comma 70 and 4 comma 160.